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base: programmerjake:ac99caa3b6dac10a610f0a593508ea07d98a2e8c
Branches Tags
programmerjake:master
programmerjake:decode-and-test-harness
libre-chip:master
libre-chip:wip-splitting-reg-alloc
...
compare: programmerjake:83b3f7bac9d6e5c68dd03843b696fd3c6a3ee4b6
Branches Tags
programmerjake:decode-and-test-harness
programmerjake:master
libre-chip:master
libre-chip:wip-splitting-reg-alloc

3 commits
ac99caa3b6 ... 83b3f7bac9

Author SHA1 Message Date
Jacob Lifshay
83b3f7bac9
use custom debug 2026-05-03 23:35:19 -07:00
Jacob Lifshay
ba9ec3bd29
adapt code for new fayalite features 2026-05-03 23:35:19 -07:00
Jacob Lifshay
1229d9c758
update fayalite for optimizations and new features 2026-05-03 23:35:19 -07:00
11 changed files with 258 additions and 755 deletions
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8
Cargo.lock generated
View file

@ -388,7 +388,7 @@ checksum = "e8c02a5121d4ea3eb16a80748c74f5549a5665e4c21333c6098f283870fbdea6"
[[package]]
name = "fayalite"
version = "0.3.0"
source = "git+https://git.libre-chip.org/libre-chip/fayalite.git?branch=master#80b92c7dd3adcad8487a3f8224846e381219bfa6"
source = "git+https://git.libre-chip.org/libre-chip/fayalite.git?branch=master#226631594458f4137739baf98d2a9cd2c257242e"
dependencies = [
"base64",
"bitvec",
@ -417,7 +417,7 @@ dependencies = [
[[package]]
name = "fayalite-proc-macros"
version = "0.3.0"
source = "git+https://git.libre-chip.org/libre-chip/fayalite.git?branch=master#80b92c7dd3adcad8487a3f8224846e381219bfa6"
source = "git+https://git.libre-chip.org/libre-chip/fayalite.git?branch=master#226631594458f4137739baf98d2a9cd2c257242e"
dependencies = [
"fayalite-proc-macros-impl",
]
@ -425,7 +425,7 @@ dependencies = [
[[package]]
name = "fayalite-proc-macros-impl"
version = "0.3.0"
source = "git+https://git.libre-chip.org/libre-chip/fayalite.git?branch=master#80b92c7dd3adcad8487a3f8224846e381219bfa6"
source = "git+https://git.libre-chip.org/libre-chip/fayalite.git?branch=master#226631594458f4137739baf98d2a9cd2c257242e"
dependencies = [
"base16ct 0.2.0",
"num-bigint",
@ -440,7 +440,7 @@ dependencies = [
[[package]]
name = "fayalite-visit-gen"
version = "0.3.0"
source = "git+https://git.libre-chip.org/libre-chip/fayalite.git?branch=master#80b92c7dd3adcad8487a3f8224846e381219bfa6"
source = "git+https://git.libre-chip.org/libre-chip/fayalite.git?branch=master#226631594458f4137739baf98d2a9cd2c257242e"
dependencies = [
"indexmap",
"prettyplease",

29
crates/cpu/src/fetch.rs
View file

@ -523,7 +523,7 @@ impl<C: PhantomConstCpuConfig> L1ICacheStateSim<C> {
kind,
read_data,
config: _,
} = memory_operation_finish;
} = memory_operation_finish.into_sim_value();
#[hdl(sim)]
match kind {
MemoryOperationFinishKind::Success(success) =>
@ -746,7 +746,7 @@ impl<C: PhantomConstCpuConfig> L1ICacheStateSim<C> {
let NextPcToFetchInterfaceInner {
start_pc,
fetch_block_id,
} = fetch;
} = fetch.into_sim_value();
let entry_ty = FetchQueueEntry[config];
self.queue.push_back(
#[hdl(sim)]
@ -895,7 +895,7 @@ impl<C: PhantomConstCpuConfig> L1ICacheStateSim<C> {
let CacheReadData::<_> {
cache_line_index: read_cache_line_index,
cache_line,
} = cache_read_data;
} = cache_read_data.into_sim_value();
let config = self.config();
for entry in &mut self.queue {
#[hdl(sim)]
@ -1151,8 +1151,6 @@ fn l1_i_cache_impl(config: PhantomConst<CpuConfig>) {
sim.wait_for_clock_edge(cd.clk).await;
}
sim.write(from_next_pc.cancel.ready, true).await;
let memory_interface_start_data_ty = memory_interface.start.data.ty();
let to_decode_fetched_data_ty = to_decode_fetched.data.ty();
let cache_read_data_ty = CacheReadData[config];
let mut state = L1ICacheStateSim::new(state_expr);
loop {
@ -1168,26 +1166,11 @@ fn l1_i_cache_impl(config: PhantomConst<CpuConfig>) {
.await;
sim.write(
memory_interface.start.data,
if let Some(v) = state.clone().try_start_memory_operation() {
#[hdl(sim)]
memory_interface_start_data_ty.HdlSome(v)
} else {
#[hdl(sim)]
memory_interface_start_data_ty.HdlNone()
},
)
.await;
sim.write(
to_decode_fetched.data,
if let Some(v) = state.clone().to_decode_fetched() {
#[hdl(sim)]
to_decode_fetched_data_ty.HdlSome(v)
} else {
#[hdl(sim)]
to_decode_fetched_data_ty.HdlNone()
},
state.clone().try_start_memory_operation(),
)
.await;
sim.write(to_decode_fetched.data, state.clone().to_decode_fetched())
.await;
state.write_debug_state(&mut sim).await;
sim.write(max_cancel_in_fetch, state.queue.len()).await;
state

579
crates/cpu/src/instruction.rs
View file

@ -12,7 +12,7 @@ use fayalite::{
intern::Interned,
module::wire_with_loc,
prelude::*,
ty::{StaticType, TypeProperties},
ty::{SimValueDebug, StaticType, TypeProperties},
util::ConstBool,
};
use std::{
@ -86,14 +86,6 @@ pub trait MOpVisitVariants: MOpTrait {
VisitOps::Target: MOpTrait<DestReg = Self::DestReg, SrcRegWidth = Self::SrcRegWidth>;
}
pub trait MOpDebug: MOpTrait {
fn mop_debug(this: &SimValue<Self>, f: &mut fmt::Formatter<'_>) -> fmt::Result;
}
pub trait MOpImmDebug: Type {
fn mop_imm_debug(this: &SimValue<Self>, f: &mut fmt::Formatter<'_>) -> fmt::Result;
}
pub trait MOpTrait: Type {
type Mapped<NewDestReg: Type, NewSrcRegWidth: Size>: MOpTrait<DestReg = NewDestReg, SrcRegWidth = NewSrcRegWidth>;
type DestReg: Type;
@ -381,7 +373,7 @@ impl<T: CommonMOpTrait> MOpVisitVariants for T {
}
}
#[hdl]
#[hdl(cmp_eq)]
pub enum OutputIntegerMode {
Full64,
DupLow32,
@ -410,40 +402,6 @@ impl OutputIntegerMode {
}
}
impl HdlPartialEqImpl<Self> for OutputIntegerMode {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
SimValue::opaque(&SimValue::from_value(lhs, lhs_value.into_owned()))
== SimValue::opaque(&SimValue::from_value(rhs, rhs_value.into_owned()))
}
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) == SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) != SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
lhs.cast_to_bits().cmp_eq(rhs.cast_to_bits())
}
}
pub const MOP_IMM_WIDTH: usize = 34;
pub const MOP_MIN_REG_WIDTH: usize = 8;
pub const COMMON_MOP_SRC_LEN: usize = 3;
@ -494,9 +452,12 @@ impl<SrcCount: KnownSize> fmt::Debug for CommonMOpDefaultImm<SrcCount> {
}
}
impl<SrcCount: KnownSize> MOpImmDebug for CommonMOpDefaultImm<SrcCount> {
fn mop_imm_debug(this: &SimValue<Self>, f: &mut fmt::Formatter<'_>) -> fmt::Result {
<SIntValue as fmt::Display>::fmt(this, f)
impl<SrcCount: KnownSize> SimValueDebug for CommonMOpDefaultImm<SrcCount> {
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
<SIntValue as fmt::Display>::fmt(value, f)
}
}
@ -625,7 +586,7 @@ impl<SrcCount: KnownSize> HdlPartialEqImpl<Self> for CommonMOpDefaultImm<SrcCoun
}
}
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct CommonMOp<
PrefixPad: KnownSize,
DestReg: Type,
@ -639,6 +600,17 @@ pub struct CommonMOp<
pub imm: Imm,
}
impl<PrefixPad: KnownSize, DestReg: Type, SrcRegWidth: Size, SrcCount: KnownSize, Imm: Type>
SimValueDebug for CommonMOp<PrefixPad, DestReg, SrcRegWidth, SrcCount, Imm>
{
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
fmt::Display::fmt(&Self::mop_debug(value, true), f)
}
}
impl<PrefixPad: KnownSize, DestReg: Type, SrcRegWidth: Size, SrcCount: KnownSize, Imm: Type>
CommonMOp<PrefixPad, DestReg, SrcRegWidth, SrcCount, Imm>
{
@ -652,32 +624,11 @@ impl<PrefixPad: KnownSize, DestReg: Type, SrcRegWidth: Size, SrcCount: KnownSize
// we should probably add padding to `CommonMOp` after `src` to compensate
// assert!(self.src.element().width() >= MOP_MIN_REG_WIDTH, "{self:#?}");
}
fn debug_dest(this: &SimValue<Self>) -> impl fmt::Debug {
use std::any::Any;
fmt::from_fn(move |f| {
if let Some(dest) = <dyn Any>::downcast_ref::<SimValue<MOpDestReg>>(&this.dest) {
f.debug_set()
.entries(
MOpDestReg::regs_sim(dest)
.into_iter()
.filter(|&v| v != MOpRegNum::CONST_ZERO_REG_NUM),
)
.finish()
} else if let Some(dest) =
<dyn Any>::downcast_ref::<SimValue<PRegNum<PhantomConst<CpuConfig>>>>(&this.dest)
{
fmt::Debug::fmt(&PRegNum::debug_sim(dest), f)
} else if let Some(dest) = <dyn Any>::downcast_ref::<
SimValue<UnitOutRegNum<PhantomConst<CpuConfig>>>,
>(&this.dest)
{
fmt::Debug::fmt(&UnitOutRegNum::debug_sim(dest), f)
} else {
fmt::Debug::fmt(&this.dest, f)
}
})
}
fn debug_sources(this: &SimValue<Self>, is_first: bool, is_last: bool) -> impl fmt::Display {
fn debug_sources(
this: &<Self as Type>::SimValue,
is_first: bool,
is_last: bool,
) -> impl fmt::Display {
fmt::from_fn(move |f| {
let mut need_comma = !is_first;
for src in &this.src {
@ -694,15 +645,12 @@ impl<PrefixPad: KnownSize, DestReg: Type, SrcRegWidth: Size, SrcCount: KnownSize
}
})
}
fn mop_debug(this: &SimValue<Self>, debug_imm: bool) -> impl fmt::Display
where
Imm: MOpImmDebug,
{
fn mop_debug(this: &<Self as Type>::SimValue, debug_imm: bool) -> impl fmt::Display {
fmt::from_fn(move |f| {
fmt::Debug::fmt(&Self::debug_dest(this), f)?;
write!(f, "{:?}", this.dest)?;
fmt::Display::fmt(&Self::debug_sources(this, false, !debug_imm), f)?;
if debug_imm {
MOpImmDebug::mop_imm_debug(&this.imm, f)?;
fmt::Debug::fmt(&this.imm, f)?;
}
Ok(())
})
@ -814,7 +762,7 @@ pub const COMMON_MOP_3_IMM_WIDTH: usize = common_mop_max_imm_size(3);
macro_rules! common_mop_struct {
(
#[debug($(#[$hdl:ident])? |$debug_this:ident, $debug_f:ident| $debug_block:block $(where $($debug_where:tt)*)?)]
#[debug($(#[$debug_hdl:ident])? |$debug_value:ident, $debug_f:ident| $debug_block:block $(where $($debug_where:tt)*)?)]
#[mapped(<$NewDestReg:ident, $SrcRegWidth:ident> $mapped_ty:ty)]
$(#[$struct_meta:meta])*
$vis:vis struct $MOp:ident<$($Generic:ident: $GenericBound:ident),* $(,)?> {
@ -841,11 +789,11 @@ macro_rules! common_mop_struct {
}
}
impl<$($Generic: $GenericBound),*> MOpDebug for $MOp<$($Generic),*>
impl<$($Generic: $GenericBound),*> SimValueDebug for $MOp<$($Generic),*>
$(where $($debug_where)*)?
{
$(#[$hdl])?
fn mop_debug($debug_this: &SimValue<Self>, $debug_f: &mut fmt::Formatter<'_>) -> fmt::Result $debug_block
$(#[$debug_hdl])?
fn sim_value_debug($debug_value: &<Self as Type>::SimValue, $debug_f: &mut fmt::Formatter<'_>) -> fmt::Result $debug_block
}
};
(
@ -959,7 +907,6 @@ macro_rules! common_mop_struct {
macro_rules! mop_enum {
(
$(#[debug(where $($debug_where:tt)*)])?
#[impl_mop_into = $impl_mop_into:tt]
$(#[$enum_meta:meta])*
$vis:vis enum $MOp:ident<
@ -1028,23 +975,21 @@ macro_rules! mop_enum {
impl<
$DestReg: Type,
$SrcRegWidth: Size,
$($MOpTypes: Type + MOpTrait<DestReg = $DestReg, SrcRegWidth = $SrcRegWidth>,)*
$($MOpTypes: Type,)*
$($Sizes: Size,)*
> crate::instruction::MOpDebug for $MOp<
> fayalite::ty::SimValueDebug for $MOp<
$DestReg,
$SrcRegWidth,
$($MOpTypes,)*
$($Sizes,)*
>
$(where $($debug_where)*)?
{
> {
#[hdl]
fn mop_debug(this: &SimValue<Self>, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
fn sim_value_debug(this: &<Self as Type>::SimValue, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
#![allow(unreachable_patterns)]
#[hdl(sim)]
match this {
Self::$FirstVariant(v) => <$first_ty as crate::instruction::MOpDebug>::mop_debug(v, f),
$(Self::$Variant(v) => <$ty as crate::instruction::MOpDebug>::mop_debug(v, f),)*
Self::$FirstVariant(v) => std::fmt::Debug::fmt(v, f),
$(Self::$Variant(v) => std::fmt::Debug::fmt(v, f),)*
_ => std::fmt::Debug::fmt(this, f),
}
}
@ -1383,7 +1328,7 @@ common_mop_struct! {
}
}
impl<DestReg: Type, SrcRegWidth: Size, SrcCount: KnownSize, Imm: MOpImmDebug>
impl<DestReg: Type, SrcRegWidth: Size, SrcCount: KnownSize, Imm: Type>
AluCommonMOp<DestReg, SrcRegWidth, SrcCount, Imm>
{
#[hdl]
@ -1441,7 +1386,7 @@ common_mop_struct! {
maybe_write_comma_flag!(f, add_pc, **add_pc)
})]
#[mapped(<NewDestReg, NewSrcRegWidth> AddSubMOp<NewDestReg, NewSrcRegWidth, SrcCount>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct AddSubMOp<DestReg: Type, SrcRegWidth: Size, SrcCount: KnownSize> {
#[common]
pub alu_common: AluCommonMOp<DestReg, SrcRegWidth, SrcCount, CommonMOpDefaultImm<SrcCount>>,
@ -1602,7 +1547,7 @@ impl Lut4 {
}
/// immediate values for [`LogicalFlagsMOp`]. See [`LogicalFlagsMOp`] for a description of the operation.
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct LogicalFlagsMOpImm {
pub src0_start: UIntInRange<0, { PRegFlags::FLAG_COUNT }>,
pub src1_start: UIntInRange<0, { PRegFlags::FLAG_COUNT }>,
@ -1611,17 +1556,20 @@ pub struct LogicalFlagsMOpImm {
pub dest_count: UIntInRangeInclusive<0, { PRegFlags::FLAG_COUNT }>,
}
impl MOpImmDebug for LogicalFlagsMOpImm {
impl SimValueDebug for LogicalFlagsMOpImm {
#[hdl]
fn mop_imm_debug(this: &SimValue<Self>, f: &mut fmt::Formatter<'_>) -> fmt::Result {
#[hdl(sim)]
let Self {
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
type SimValueT<T> = <T as Type>::SimValue;
let SimValueT::<Self> {
src0_start,
src1_start,
src2_start,
dest_start,
dest_count,
} = this;
} = value;
write!(
f,
"{{[{dest_start}..][..{dest_count}] <= [{src0_start}..], [{src1_start}..], [{src2_start}..]}}"
@ -1843,7 +1791,7 @@ impl LogicalFlagsMOpImm {
src2_start,
dest_start,
dest_count,
} = this;
} = this.into_sim_value();
Self::flags_operation_impl(
src0_start,
src1_start,
@ -2018,7 +1966,7 @@ common_mop_struct! {
write!(f, "LogicalFlags {common}, {:?}", lut.lut)
})]
#[mapped(<NewDestReg, NewSrcRegWidth> LogicalFlagsMOp<NewDestReg, NewSrcRegWidth>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
/// Operation:
/// ```
/// # // set up a bunch of mock types and variables -- they don't necessarily match the real types
@ -2182,7 +2130,7 @@ common_mop_struct! {
write!(f, "Logical {alu_common}, {:?}", lut.lut)
})]
#[mapped(<NewDestReg, NewSrcRegWidth> LogicalMOp<NewDestReg, NewSrcRegWidth, SrcCount>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct LogicalMOp<DestReg: Type, SrcRegWidth: Size, SrcCount: KnownSize> {
#[common]
pub alu_common: AluCommonMOp<DestReg, SrcRegWidth, SrcCount, CommonMOpDefaultImm<SrcCount>>,
@ -2254,7 +2202,7 @@ impl<DestReg: Type, SrcRegWidth: Size> LogicalMOp<DestReg, SrcRegWidth, ConstUsi
}
}
#[hdl]
#[hdl(cmp_eq)]
pub enum ShiftRotateMode {
/// like `llvm.fsh[lr].i8(src0, src1, shift_rotate_amount.unwrap_or(src2))`
FunnelShift2x8Bit,
@ -2274,40 +2222,6 @@ pub enum ShiftRotateMode {
ShiftSigned64,
}
impl HdlPartialEqImpl<Self> for ShiftRotateMode {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
SimValue::opaque(&SimValue::from_value(lhs, lhs_value.into_owned()))
== SimValue::opaque(&SimValue::from_value(rhs, rhs_value.into_owned()))
}
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) == SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) != SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
lhs.cast_to_bits().cmp_eq(rhs.cast_to_bits())
}
}
impl ShiftRotateMode {
#[hdl]
fn debug_str(this: &SimValue<Self>) -> &'static str {
@ -2407,7 +2321,7 @@ impl ShiftRotateDestLogicOp {
}
/// immediate values for [`ShiftRotateMOp`].
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct ShiftRotateMOpImm {
/// taken from `src2` if this is [`HdlNone`]
pub shift_rotate_amount: HdlOption<UInt<6>>,
@ -2416,15 +2330,18 @@ pub struct ShiftRotateMOpImm {
pub dest_logic_op: HdlOption<ShiftRotateDestLogicOp>,
}
impl MOpImmDebug for ShiftRotateMOpImm {
impl SimValueDebug for ShiftRotateMOpImm {
#[hdl]
fn mop_imm_debug(this: &SimValue<Self>, f: &mut fmt::Formatter<'_>) -> fmt::Result {
#[hdl(sim)]
let Self {
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
type SimValueT<T> = <T as Type>::SimValue;
let SimValueT::<Self> {
shift_rotate_amount,
shift_rotate_right,
dest_logic_op,
} = this;
} = value;
let shift_op = if **shift_rotate_right { ">>" } else { "<<" };
#[hdl(sim)]
match shift_rotate_amount {
@ -2465,7 +2382,7 @@ common_mop_struct! {
write!(f, "ShiftRotate {alu_common}, {:?}", ShiftRotateMode::debug_str(mode))
})]
#[mapped(<NewDestReg, NewSrcRegWidth> ShiftRotateMOp<NewDestReg, NewSrcRegWidth>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct ShiftRotateMOp<DestReg: Type, SrcRegWidth: Size> {
#[common]
pub alu_common: AluCommonMOp<DestReg, SrcRegWidth, ConstUsize<3>, ShiftRotateMOpImm>,
@ -2505,7 +2422,7 @@ impl<DestReg: Type, SrcRegWidth: Size> ShiftRotateMOp<DestReg, SrcRegWidth> {
}
}
#[hdl]
#[hdl(cmp_eq)]
pub enum CompareMode {
U64,
S64,
@ -2523,40 +2440,6 @@ pub enum CompareMode {
CmpEqB,
}
impl HdlPartialEqImpl<Self> for CompareMode {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
SimValue::opaque(&SimValue::from_value(lhs, lhs_value.into_owned()))
== SimValue::opaque(&SimValue::from_value(rhs, rhs_value.into_owned()))
}
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) == SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) != SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
lhs.cast_to_bits().cmp_eq(rhs.cast_to_bits())
}
}
impl CompareMode {
#[hdl]
fn debug_str(this: &SimValue<Self>) -> &'static str {
@ -2589,7 +2472,7 @@ common_mop_struct! {
write!(f, "Compare {common}, {}", CompareMode::debug_str(compare_mode))
})]
#[mapped(<NewDestReg, NewSrcRegWidth> CompareMOp<NewDestReg, NewSrcRegWidth, SrcCount>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct CompareMOp<DestReg: Type, SrcRegWidth: Size, SrcCount: KnownSize> {
#[common]
pub common: CommonMOp<ConstUsize<0>, DestReg, SrcRegWidth, SrcCount, CommonMOpDefaultImm<SrcCount>>,
@ -2652,7 +2535,7 @@ impl<DestReg: Type, SrcRegWidth: Size> CompareMOp<DestReg, SrcRegWidth, ConstUsi
}
}
#[hdl]
#[hdl(cmp_eq)]
pub enum ConditionMode {
Eq,
ULt,
@ -2664,40 +2547,6 @@ pub enum ConditionMode {
Parity,
}
impl HdlPartialEqImpl<Self> for ConditionMode {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
SimValue::opaque(&SimValue::from_value(lhs, lhs_value.into_owned()))
== SimValue::opaque(&SimValue::from_value(rhs, rhs_value.into_owned()))
}
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) == SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) != SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
lhs.cast_to_bits().cmp_eq(rhs.cast_to_bits())
}
}
impl ConditionMode {
#[hdl]
fn debug_str(this: &SimValue<Self>, inverted: bool) -> &'static str {
@ -2736,7 +2585,7 @@ common_mop_struct! {
maybe_write_comma_flag!(f, is_ret, **is_ret)
})]
#[mapped(<NewDestReg, NewSrcRegWidth> BranchMOp<NewDestReg, NewSrcRegWidth, SrcCount>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
/// `src0` is the value used for reading flags from.
/// `src1 + imm + if pc_relative { pc } else { 0 }` is the target address.
/// `src2` (if present) is the counter to compare against zero.
@ -2892,63 +2741,12 @@ impl<DestReg: Type, SrcRegWidth: Size> BranchMOp<DestReg, SrcRegWidth, ConstUsiz
}
}
#[hdl]
#[hdl(cmp_eq)]
pub enum ReadSpecialMOpImm {
PowerIsaTimeBase,
PowerIsaTimeBaseU,
}
impl HdlPartialEqImpl<Self> for ReadSpecialMOpImm {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
SimValue::opaque(&SimValue::from_value(lhs, lhs_value.into_owned()))
== SimValue::opaque(&SimValue::from_value(rhs, rhs_value.into_owned()))
}
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) == SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) != SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
lhs.cast_to_bits().cmp_eq(rhs.cast_to_bits())
}
}
impl MOpImmDebug for ReadSpecialMOpImm {
fn mop_imm_debug(this: &SimValue<Self>, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.write_str(Self::debug_str(this))
}
}
impl ReadSpecialMOpImm {
#[hdl]
fn debug_str(this: &SimValue<Self>) -> &'static str {
#[hdl(sim)]
match this {
Self::PowerIsaTimeBase => "PowerIsaTimeBase",
Self::PowerIsaTimeBaseU => "PowerIsaTimeBaseU",
}
}
}
common_mop_struct! {
#[debug(#[hdl] |this, f| {
#[hdl(sim)]
@ -2959,7 +2757,7 @@ common_mop_struct! {
write!(f, "ReadSpecial {common}")
})]
#[mapped(<NewDestReg, NewSrcRegWidth> ReadSpecialMOp<NewDestReg, NewSrcRegWidth>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct ReadSpecialMOp<DestReg: Type, SrcRegWidth: Size> {
#[common]
pub common: CommonMOp<ConstUsize<0>, DestReg, SrcRegWidth, ConstUsize<0>, ReadSpecialMOpImm>,
@ -2993,7 +2791,7 @@ impl<DestReg: Type, SrcRegWidth: Size> ReadSpecialMOp<DestReg, SrcRegWidth> {
mop_enum! {
#[impl_mop_into = true]
#[hdl]
#[hdl(custom_debug(sim))]
pub enum AluBranchMOp<DestReg: Type, SrcRegWidth: Size> {
AddSub(AddSubMOp<DestReg, SrcRegWidth, ConstUsize<3>>),
AddSubI(AddSubMOp<DestReg, SrcRegWidth, ConstUsize<2>>),
@ -3009,7 +2807,7 @@ mop_enum! {
}
}
#[hdl]
#[hdl(custom_debug(sim))]
pub struct L2RegNum {
pub value: UInt<{ MOpRegNum::WIDTH }>,
}
@ -3028,14 +2826,14 @@ impl L2RegNum {
value: u8::try_from(value).expect("value must fit"),
}
}
pub fn debug_sim(this: &SimValue<Self>) -> impl fmt::Debug {
fmt::from_fn(move |f| write!(f, "l2r{:#x}", Self::value_sim(this)))
}
}
impl MOpImmDebug for L2RegNum {
fn mop_imm_debug(this: &SimValue<Self>, f: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt::Debug::fmt(&Self::debug_sim(this), f)
impl SimValueDebug for L2RegNum {
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
write!(f, "l2r{:#x}", value.value.as_int())
}
}
@ -3049,7 +2847,7 @@ common_mop_struct! {
write!(f, "ReadL2Reg {common}")
})]
#[mapped(<NewDestReg, NewSrcRegWidth> ReadL2RegMOp<NewDestReg, NewSrcRegWidth>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct ReadL2RegMOp<DestReg: Type, SrcRegWidth: Size> {
#[common]
pub common: CommonMOp<ConstUsize<3>, DestReg, SrcRegWidth, ConstUsize<0>, L2RegNum>,
@ -3091,7 +2889,7 @@ common_mop_struct! {
write!(f, "WriteL2Reg {common}")
})]
#[mapped(<NewDestReg, NewSrcRegWidth> WriteL2RegMOp<NewDestReg, NewSrcRegWidth>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct WriteL2RegMOp<DestReg: Type, SrcRegWidth: Size> {
#[common]
pub common: CommonMOp<ConstUsize<3>, DestReg, SrcRegWidth, ConstUsize<1>, L2RegNum>,
@ -3125,7 +2923,7 @@ impl<DestReg: Type, SrcRegWidth: Size> WriteL2RegMOp<DestReg, SrcRegWidth> {
mop_enum! {
#[impl_mop_into = true]
#[hdl]
#[hdl(custom_debug(sim))]
pub enum L2RegisterFileMOp<DestReg: Type, SrcRegWidth: Size> {
ReadL2Reg(ReadL2RegMOp<DestReg, SrcRegWidth>),
WriteL2Reg(WriteL2RegMOp<DestReg, SrcRegWidth>),
@ -3151,7 +2949,7 @@ where
}
}
#[hdl]
#[hdl(cmp_eq)]
pub enum LoadStoreWidth {
Width8Bit,
Width16Bit,
@ -3159,81 +2957,13 @@ pub enum LoadStoreWidth {
Width64Bit,
}
impl HdlPartialEqImpl<Self> for LoadStoreWidth {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
SimValue::opaque(&SimValue::from_value(lhs, lhs_value.into_owned()))
== SimValue::opaque(&SimValue::from_value(rhs, rhs_value.into_owned()))
}
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) == SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) != SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
lhs.cast_to_bits().cmp_eq(rhs.cast_to_bits())
}
}
#[hdl]
#[hdl(cmp_eq)]
pub enum LoadStoreConversion {
ZeroExt,
SignExt,
// TODO(FP): add Power ISA's f32 in f64 format and RISC-V's ones-extension of floating-point
}
impl HdlPartialEqImpl<Self> for LoadStoreConversion {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
SimValue::opaque(&SimValue::from_value(lhs, lhs_value.into_owned()))
== SimValue::opaque(&SimValue::from_value(rhs, rhs_value.into_owned()))
}
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) == SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::opaque(&lhs) != SimValue::opaque(&rhs)).to_sim_value()
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
lhs.cast_to_bits().cmp_eq(rhs.cast_to_bits())
}
}
common_mop_struct! {
#[mapped(<NewDestReg, NewSrcRegWidth> LoadStoreCommonMOp<NewDestReg, NewSrcRegWidth, SrcCount>)]
#[hdl(cmp_eq)]
@ -3309,7 +3039,7 @@ common_mop_struct! {
write!(f, "Load {load_store_common}")
})]
#[mapped(<NewDestReg, NewSrcRegWidth> LoadMOp<NewDestReg, NewSrcRegWidth>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct LoadMOp<DestReg: Type, SrcRegWidth: Size> {
#[common]
pub load_store_common: LoadStoreCommonMOp<DestReg, SrcRegWidth, ConstUsize<1>>,
@ -3357,7 +3087,7 @@ common_mop_struct! {
write!(f, "Store {load_store_common}")
})]
#[mapped(<NewDestReg, NewSrcRegWidth> StoreMOp<NewDestReg, NewSrcRegWidth>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
/// does `*src0 = convert(src1)`
pub struct StoreMOp<DestReg: Type, SrcRegWidth: Size> {
#[common]
@ -3398,7 +3128,7 @@ impl<DestReg: Type, SrcRegWidth: Size> StoreMOp<DestReg, SrcRegWidth> {
mop_enum! {
#[impl_mop_into = true]
#[hdl]
#[hdl(custom_debug(sim))]
pub enum LoadStoreMOp<DestReg: Type, SrcRegWidth: Size> {
Load(LoadMOp<DestReg, SrcRegWidth>),
Store(StoreMOp<DestReg, SrcRegWidth>),
@ -3415,7 +3145,7 @@ common_mop_struct! {
write!(f, "MoveReg {common}")
})]
#[mapped(<NewDestReg, NewSrcRegWidth> MoveRegMOp<NewDestReg, NewSrcRegWidth>)]
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
pub struct MoveRegMOp<DestReg: Type, SrcRegWidth: Size> {
#[common]
pub common: CommonMOp<ConstUsize<4>, DestReg, SrcRegWidth, ConstUsize<1>, CommonMOpDefaultImm<ConstUsize<1>>>,
@ -3465,7 +3195,7 @@ impl<DestReg: Type, SrcRegWidth: Size> MoveRegMOp<DestReg, SrcRegWidth> {
}
}
#[hdl(cmp_eq, no_static)]
#[hdl(cmp_eq, no_static, custom_debug(sim))]
/// there may be more than one unit of a given kind, so UnitNum is not the same as UnitKind.
/// zero is used for built-in constants, such as the zero register
pub struct UnitNum<C: PhantomConstGet<CpuConfig>> {
@ -3473,6 +3203,30 @@ pub struct UnitNum<C: PhantomConstGet<CpuConfig>> {
pub config: C,
}
impl<C: Type + PhantomConstGet<CpuConfig>> SimValueDebug for UnitNum<C> {
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
if let Some(index) = Self::index_sim(value) {
write!(f, "u{index}")
} else {
f.write_str("uz")
}
}
}
impl<C: Type + PhantomConstGet<CpuConfig>> UnitNum<C> {
pub fn index_sim(expr: &<Self as Type>::SimValue) -> Option<usize> {
let adj_value = expr.adj_value.cast_to_static::<UInt<32>>().as_int();
if adj_value == 0 {
None
} else {
Some(adj_value as usize - 1)
}
}
}
impl<C: PhantomConstCpuConfig> UnitNum<C> {
pub fn const_zero(self) -> Expr<Self> {
self.const_zero_sim().to_expr()
@ -3500,14 +3254,6 @@ impl<C: PhantomConstCpuConfig> UnitNum<C> {
let expr = expr.to_expr();
expr.ty().from_index(index).adj_value.cmp_eq(expr.adj_value)
}
pub fn index_sim(expr: &SimValue<Self>) -> Option<usize> {
let adj_value = expr.adj_value.cast_to_static::<UInt<32>>().as_int();
if adj_value == 0 {
None
} else {
Some(adj_value as usize - 1)
}
}
#[hdl]
pub fn as_index(
expr: impl ToExpr<Type = Self>,
@ -3525,25 +3271,32 @@ impl<C: PhantomConstCpuConfig> UnitNum<C> {
}
unit_index
}
pub fn debug_sim(this: &SimValue<Self>) -> impl fmt::Debug {
fmt::from_fn(move |f| {
if let Some(index) = Self::index_sim(this) {
write!(f, "u{index}")
} else {
f.write_str("uz")
}
})
}
}
pub const CONST_ZERO_UNIT_NUM: usize = 0;
#[hdl(cmp_eq, no_static)]
#[hdl(cmp_eq, no_static, custom_debug(sim))]
pub struct UnitOutRegNum<C: PhantomConstGet<CpuConfig>> {
pub value: UIntType<CpuConfigOutRegNumWidth<C>>,
pub config: C,
}
impl<C: Type + PhantomConstGet<CpuConfig>> SimValueDebug for UnitOutRegNum<C> {
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
let value = Self::value_sim(value);
write!(f, "or{value:#x}")
}
}
impl<C: Type + PhantomConstGet<CpuConfig>> UnitOutRegNum<C> {
pub fn value_sim(this: &<Self as Type>::SimValue) -> usize {
this.value.cast_to_static::<UInt<64>>().as_int() as usize
}
}
impl<C: PhantomConstCpuConfig> UnitOutRegNum<C> {
#[hdl]
pub fn new_sim(self, value: usize) -> SimValue<Self> {
@ -3553,16 +3306,9 @@ impl<C: PhantomConstCpuConfig> UnitOutRegNum<C> {
config: self.config,
}
}
pub fn value_sim(this: &SimValue<Self>) -> usize {
this.value.cast_to_static::<UInt<64>>().as_int() as usize
}
pub fn debug_sim(this: &SimValue<Self>) -> impl fmt::Debug {
let value = Self::value_sim(this);
fmt::from_fn(move |f| write!(f, "or{value:#x}"))
}
}
#[hdl(cmp_eq, no_static)]
#[hdl(cmp_eq, no_static, custom_debug(sim))]
/// Physical Register Number -- registers in the CPU's backend
pub struct PRegNum<C: PhantomConstGet<CpuConfig>> {
pub unit_num: UnitNum<C>,
@ -3582,27 +3328,20 @@ impl<C: PhantomConstCpuConfig> PRegNum<C> {
},
}
}
#[hdl]
pub fn debug_sim(this: &SimValue<Self>) -> impl fmt::Debug {
fmt::from_fn(move |f| {
#[hdl(sim)]
let Self {
unit_num,
unit_out_reg,
} = this;
if let (None, 0) = (
UnitNum::index_sim(unit_num),
UnitOutRegNum::value_sim(unit_out_reg),
) {
return f.write_str("pzero");
}
write!(
f,
"p{:?}_{:?}",
UnitNum::debug_sim(unit_num),
UnitOutRegNum::debug_sim(unit_out_reg),
)
})
}
impl<C: Type + PhantomConstGet<CpuConfig>> SimValueDebug for PRegNum<C> {
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
if let (None, 0) = (
UnitNum::index_sim(&value.unit_num),
UnitOutRegNum::value_sim(&value.unit_out_reg),
) {
return f.write_str("pzero");
}
write!(f, "p{:?}_{:?}", &value.unit_num, &value.unit_out_reg)
}
}
@ -3644,7 +3383,7 @@ impl MOpRegNum {
Self::CONST_ZERO_REG_NUM + 1..Self::SPECIAL_REG_NUMS.start;
}
#[hdl(cmp_eq)]
#[hdl(cmp_eq, custom_debug(sim))]
/// all the registers this instruction will write to, they are all renamed to the same physical register.
pub struct MOpDestReg {
/// some instructions have multiple destination registers, e.g. x86 div
@ -3656,6 +3395,33 @@ pub struct MOpDestReg {
pub flag_regs: Array<HdlOption<()>, { range_u32_len(&MOpRegNum::FLAG_REG_NUMS) }>,
}
impl SimValueDebug for MOpDestReg {
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
if f.alternate() {
type SimValueT<T> = <T as Type>::SimValue;
let SimValueT::<Self> {
normal_regs,
flag_regs,
} = value;
f.debug_struct("MOpDestReg")
.field("normal_regs", normal_regs)
.field("flag_regs", flag_regs)
.finish()
} else {
f.debug_set()
.entries(
Self::regs_sim(value)
.into_iter()
.filter(|&v| v != MOpRegNum::CONST_ZERO_REG_NUM),
)
.finish()
}
}
}
impl MOpDestReg {
#[hdl]
#[track_caller]
@ -3890,8 +3656,7 @@ impl MOpDestReg {
})
}
#[hdl]
pub fn regs_sim(this: &SimValue<Self>) -> [u32; Self::REG_COUNT] {
let this = this.into_sim_value();
pub fn regs_sim(this: &<Self as Type>::SimValue) -> [u32; Self::REG_COUNT] {
std::array::from_fn(|index| match Self::REG_KINDS[index] {
MOpDestRegKind::NormalReg { dest_reg_index } => this.normal_regs[dest_reg_index]
.value

182
crates/cpu/src/next_pc.rs
View file

@ -23,14 +23,13 @@ use crate::{
util::array_vec::ArrayVec,
};
use fayalite::{
expr::HdlPartialEqImpl,
int::{UIntInRange, UIntInRangeInclusive, UIntInRangeInclusiveType, UIntInRangeType},
prelude::*,
sim::value::SimOnlyValueTrait,
ty::StaticType,
util::{DebugAsDisplay, ready_valid::ReadyValid},
};
use std::{borrow::Cow, fmt};
use std::fmt;
pub const FETCH_BLOCK_ID_WIDTH: usize = FetchBlockIdInt::BITS as usize;
type FetchBlockIdInt = u8;
@ -53,7 +52,7 @@ pub struct NextPcToFetchInterface<C: PhantomConstGet<CpuConfig>> {
pub config: C,
}
#[hdl]
#[hdl(cmp_eq)]
/// WIP version of decoded instruction just good enough to represent stuff needed for [`next_pc()`]
/// since the actual instruction definition isn't finalized yet.
/// This will be replaced at a later point.
@ -93,101 +92,6 @@ impl WipDecodedInsnKind {
}
}
// TODO: replace with #[hdl(cmp_eq)] when that's implemented for enums
impl HdlPartialEqImpl<Self> for WipDecodedInsnKind {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
*Self::cmp_sim_value_eq(
Cow::Owned(SimValue::from_value(lhs, lhs_value.into_owned())),
Cow::Owned(SimValue::from_value(rhs, rhs_value.into_owned())),
)
}
#[hdl]
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
let clear_unused_bits = |v: Cow<'_, SimValue<Self>>| {
#[hdl(sim)]
match &*v {
Self::NonBranch =>
{
#[hdl(sim)]
Self::NonBranch()
}
Self::Branch(target) =>
{
#[hdl(sim)]
Self::Branch(target)
}
Self::BranchCond(target) =>
{
#[hdl(sim)]
Self::BranchCond(target)
}
Self::IndirectBranch =>
{
#[hdl(sim)]
Self::IndirectBranch()
}
Self::Call(target) =>
{
#[hdl(sim)]
Self::Call(target)
}
Self::CallCond(target) =>
{
#[hdl(sim)]
Self::CallCond(target)
}
Self::IndirectCall =>
{
#[hdl(sim)]
Self::IndirectCall()
}
Self::Ret =>
{
#[hdl(sim)]
Self::Ret()
}
Self::RetCond =>
{
#[hdl(sim)]
Self::RetCond()
}
Self::Interrupt(target) =>
{
#[hdl(sim)]
Self::Interrupt(target)
}
Self::Unknown => v.into_owned(),
}
};
(SimValue::bits(&clear_unused_bits(lhs)) == SimValue::bits(&clear_unused_bits(rhs)))
.to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
!Self::cmp_sim_value_eq(lhs, rhs)
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
todo!()
}
}
#[hdl(cmp_eq)]
/// WIP version of decoded instruction just good enough to represent stuff needed for [`next_pc()`]
/// since the actual instruction definition isn't finalized yet.
@ -2781,8 +2685,10 @@ impl<T: SimValueDefault, N: Size> SimValueDefault for ArrayType<T, N> {
}
impl<T: Type> SimValueDefault for HdlOption<T> {
#[hdl]
fn sim_value_default(self) -> SimValue<Self> {
self.HdlNone().to_sim_value_with_type(self)
#[hdl(sim)]
self.HdlNone()
}
}
@ -2911,50 +2817,13 @@ impl ResetSteps for CallStack {
}
}
#[hdl]
#[hdl(cmp_eq)]
enum BTBEntryInsnKind {
Branch,
Call,
Ret,
}
// TODO: replace with #[hdl(cmp_eq)] when that's implemented for enums
impl HdlPartialEqImpl<Self> for BTBEntryInsnKind {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
*Self::cmp_sim_value_eq(
Cow::Owned(SimValue::from_value(lhs, lhs_value.into_owned())),
Cow::Owned(SimValue::from_value(rhs, rhs_value.into_owned())),
)
}
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::bits(&*lhs) == SimValue::bits(&*rhs)).to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::bits(&*lhs) != SimValue::bits(&*rhs)).to_sim_value()
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
lhs.cast_to_bits().cmp_eq(rhs.cast_to_bits())
}
}
impl BTBEntryInsnKind {
#[hdl]
fn try_from_decoded_insn_kind(kind: &SimValue<WipDecodedInsnKind>) -> Option<SimValue<Self>> {
@ -2983,7 +2852,7 @@ impl BTBEntryInsnKind {
}
}
#[hdl]
#[hdl(cmp_eq)]
enum BTBEntryAddrKind {
Unconditional,
Indirect,
@ -2991,43 +2860,6 @@ enum BTBEntryAddrKind {
CondNotTaken,
}
// TODO: replace with #[hdl(cmp_eq)] when that's implemented for enums
impl HdlPartialEqImpl<Self> for BTBEntryAddrKind {
#[track_caller]
fn cmp_value_eq(
lhs: Self,
lhs_value: Cow<'_, Self::SimValue>,
rhs: Self,
rhs_value: Cow<'_, Self::SimValue>,
) -> bool {
*Self::cmp_sim_value_eq(
Cow::Owned(SimValue::from_value(lhs, lhs_value.into_owned())),
Cow::Owned(SimValue::from_value(rhs, rhs_value.into_owned())),
)
}
#[track_caller]
fn cmp_sim_value_eq(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::bits(&*lhs) == SimValue::bits(&*rhs)).to_sim_value()
}
#[track_caller]
fn cmp_sim_value_ne(
lhs: Cow<'_, SimValue<Self>>,
rhs: Cow<'_, SimValue<Self>>,
) -> SimValue<Bool> {
(SimValue::bits(&*lhs) != SimValue::bits(&*rhs)).to_sim_value()
}
#[track_caller]
fn cmp_expr_eq(lhs: Expr<Self>, rhs: Expr<Self>) -> Expr<Bool> {
lhs.cast_to_bits().cmp_eq(rhs.cast_to_bits())
}
}
impl BTBEntryAddrKind {
#[hdl]
fn taken(this: &SimValue<Self>) -> bool {

109
crates/cpu/src/rename_execute_retire.rs
View file

@ -10,8 +10,8 @@ use crate::{
CpuConfigRobSize, CpuConfigUnitCount, PhantomConstCpuConfig, TwiceCpuConfigFetchWidth,
},
instruction::{
COMMON_MOP_SRC_LEN, L2RegNum, L2RegisterFileMOp, MOp, MOpDebug, MOpDestReg, MOpRegNum,
MOpTrait, PRegNum, ReadL2RegMOp, UnitNum, UnitOutRegNum,
COMMON_MOP_SRC_LEN, L2RegNum, L2RegisterFileMOp, MOp, MOpDestReg, MOpRegNum, MOpTrait,
PRegNum, ReadL2RegMOp, UnitNum, UnitOutRegNum,
},
next_pc::{CallStackOp, SimValueDefault},
register::PRegValue,
@ -22,7 +22,7 @@ use crate::{
use fayalite::{
int::UIntInRangeInclusiveType,
prelude::*,
ty::{OpaqueSimValue, StaticType},
ty::{OpaqueSimValue, SimValueDebug, StaticType},
util::ready_valid::ReadyValid,
};
use std::{collections::VecDeque, fmt, mem, num::NonZero};
@ -33,7 +33,7 @@ pub const MOP_ID_WIDTH: usize = 16;
#[hdl]
pub type MOpId = UInt<{ MOP_ID_WIDTH }>;
#[hdl]
#[hdl(custom_debug(sim))]
/// A &micro;Op along with the state needed for this instance of the &micro;Op.
pub struct MOpInstance<MOp> {
pub fetch_block_id: UInt<8>,
@ -50,6 +50,29 @@ pub struct MOpInstance<MOp> {
pub mop: MOp,
}
impl<MOp: Type> SimValueDebug for MOpInstance<MOp> {
#[hdl]
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
#[hdl(sim)]
let Self {
fetch_block_id,
id,
pc,
predicted_next_pc,
size_in_bytes,
is_first_mop_in_insn,
mop,
} = value;
write!(
f,
"fid={fetch_block_id:?} id={id:?} pc={pc:?} pn_pc={predicted_next_pc:?} sz={size_in_bytes:?} first={is_first_mop_in_insn}: {mop:?}"
)
}
}
#[hdl(no_static)]
/// TODO: merge with [`crate::next_pc::PostDecodeOutputInterface`]
pub struct PostDecodeOutputInterface<C: PhantomConstGet<CpuConfig>> {
@ -233,16 +256,6 @@ impl<C: PhantomConstCpuConfig> RenameTableEntry<C> {
#[hdl(sim)]
self.L1(self.L1.const_zero())
}
#[hdl]
fn debug_sim(this: &SimValue<Self>) -> impl fmt::Debug {
fmt::from_fn(move |f| {
#[hdl(sim)]
match this {
Self::L1(v) => write!(f, "L1({:?})", PRegNum::debug_sim(v)),
Self::L2(v) => write!(f, "L2({:?})", L2RegNum::debug_sim(v)),
}
})
}
}
/// make arrays dynamically-sized to avoid putting large types on the stack
@ -320,10 +333,7 @@ impl<C: PhantomConstCpuConfig> RenameTable<C> {
// writing to const zero reg does nothing
return;
}
println!(
"{rename_table_name}: Write: {unrenamed_reg_num:#x} <- {:?}",
RenameTableEntry::debug_sim(new),
);
println!("{rename_table_name}: Write: {unrenamed_reg_num:#x} <- {new:?}");
self.entries[*unrenamed_reg_num as usize] = new.clone();
}
RenameTableUpdate::UpdateForReadL2Reg { dest, src } => {
@ -336,9 +346,8 @@ impl<C: PhantomConstCpuConfig> RenameTable<C> {
RenameTableEntry::<_>::L2(l2) => {
if L2RegNum::value_sim(l2) == L2RegNum::value_sim(src) {
println!(
"{rename_table_name}: UpdateForReadL2Reg: {unrenamed_reg_num:#x} updating from {:?} to {:?}",
RenameTableEntry::debug_sim(&entry),
RenameTableEntry::debug_sim(&new),
"{rename_table_name}: UpdateForReadL2Reg: {unrenamed_reg_num:#x} \
updating from {entry:?} to {new:?}",
);
*entry = new.clone();
}
@ -355,9 +364,8 @@ impl<C: PhantomConstCpuConfig> RenameTable<C> {
RenameTableEntry::<_>::L1(l1) => {
if l1 == src {
println!(
"{rename_table_name}: UpdateForWriteL2Reg: {unrenamed_reg_num:#x} updating from {:?} to {:?}",
RenameTableEntry::debug_sim(&entry),
RenameTableEntry::debug_sim(&new),
"{rename_table_name}: UpdateForWriteL2Reg: {unrenamed_reg_num:#x} \
updating from {entry:?} to {new:?}",
);
*entry = new.clone();
}
@ -635,20 +643,8 @@ impl<C: PhantomConstCpuConfig> RobEntry<C> {
mop,
mop_in_unit_state: SimOnlyValue::new(*mop_in_unit_state),
is_speculative,
finished: if let Some(finished) = finished {
#[hdl(sim)]
(ret_ty.finished).HdlSome(finished)
} else {
#[hdl(sim)]
(ret_ty.finished).HdlNone()
},
caused_cancel: if let Some(caused_cancel) = caused_cancel {
#[hdl(sim)]
(ret_ty.caused_cancel).HdlSome(caused_cancel)
} else {
#[hdl(sim)]
(ret_ty.caused_cancel).HdlNone()
},
finished: finished.into_sim_value_with_type(ret_ty.finished),
caused_cancel: caused_cancel.into_sim_value_with_type(ret_ty.caused_cancel),
}
}
}
@ -813,13 +809,7 @@ impl<C: PhantomConstCpuConfig> ReorderBuffer<C> {
entries.iter().map(RobEntries::debug_state),
)
.expect("known to fit"),
incomplete_back_entry: if let Some(incomplete_back_entry) = incomplete_back_entry {
#[hdl(sim)]
HdlSome(incomplete_back_entry.debug_state())
} else {
#[hdl(sim)]
HdlNone()
},
incomplete_back_entry: incomplete_back_entry.as_ref().map(|v| v.debug_state()),
renamed: ty
.renamed
.from_iter_sim(
@ -1036,15 +1026,15 @@ impl<C: PhantomConstCpuConfig> RenameExecuteRetireState<C> {
}
write!(
f,
": {:#x}{}: ",
": {:#x}{}: {:?}",
rob.mop.pc.as_int(),
if *rob.mop.is_first_mop_in_insn {
""
} else {
".."
},
)?;
MOpDebug::mop_debug(&rob.mop.mop, f)
rob.mop.mop,
)
})
.to_string();
// TODO
@ -1085,18 +1075,7 @@ impl<C: PhantomConstCpuConfig> RenameExecuteRetireState<C> {
l1_reg_file: SimValue::from_array_elements(
state_for_debug.ty().l1_reg_file,
l1_reg_file.iter().map(|v| {
SimValue::from_array_elements(
state_for_debug.ty().l1_reg_file.element(),
v.iter().map(|v| {
if let Some(v) = v {
#[hdl(sim)]
HdlSome(v)
} else {
#[hdl(sim)]
HdlNone()
}
}),
)
SimValue::from_array_elements(state_for_debug.ty().l1_reg_file.element(), v)
}),
),
per_insn_timeline: self.per_insn_timeline(),
@ -1249,10 +1228,7 @@ impl<C: PhantomConstCpuConfig> RenameExecuteRetireState<C> {
});
let [src_reg] = src_regs;
let renamed_reg = self.rename_table.entries[src_reg as usize].clone();
println!(
"moving from {src_reg:#x} renamed: {:?}",
RenameTableEntry::debug_sim(&renamed_reg),
);
println!("moving from {src_reg:#x} renamed: {renamed_reg:?}");
let unrenamed_dest_regs =
MOpDestReg::regs_sim(MOpTrait::dest_reg_sim_ref(move_reg_mop));
assert!(self.rob.incomplete_back_entry.is_none());
@ -1350,10 +1326,7 @@ impl<C: PhantomConstCpuConfig> RenameExecuteRetireState<C> {
CpuConfigPRegNumWidth[self.config],
&mut |src_reg, index| {
let renamed = &self.rename_table.entries[src_reg.as_int() as usize];
println!(
"renaming src[{index}] from {src_reg:?} to {:?}",
RenameTableEntry::debug_sim(renamed),
);
println!("renaming src[{index}] from {src_reg:?} to {renamed:?}");
#[hdl(sim)]
match renamed {
RenameTableEntry::<_>::L1(v) => v.cast_to_bits(),

14
crates/cpu/src/rename_execute_retire/to_unit_interfaces.rs
View file

@ -7,7 +7,10 @@ use fayalite::{
expr::ops::FieldAccess,
intern::{Intern, Interned, Memoize},
prelude::*,
ty::{OpaqueSimValue, OpaqueSimValueSlice, OpaqueSimValueWriter, OpaqueSimValueWritten},
ty::{
OpaqueSimValue, OpaqueSimValueSlice, OpaqueSimValueWriter, OpaqueSimValueWritten,
SimValueDebug,
},
};
use std::{fmt, marker::PhantomData, ops::Index};
@ -116,6 +119,15 @@ impl<C: Type + PhantomConstGet<CpuConfig>> Index<C> for ExecuteToUnitInterfacesW
}
}
impl<C: Type + PhantomConstGet<CpuConfig>> SimValueDebug for ExecuteToUnitInterfaces<C> {
fn sim_value_debug(
value: &<Self as Type>::SimValue,
f: &mut fmt::Formatter<'_>,
) -> fmt::Result {
fmt::Debug::fmt(value, f)
}
}
impl<C: Type + PhantomConstGet<CpuConfig>> Type for ExecuteToUnitInterfaces<C> {
type BaseType = Bundle;
type MaskType = Bundle;

7
crates/cpu/src/unit.rs
View file

@ -26,7 +26,7 @@ macro_rules! all_units {
(
#[hdl_unit_kind = $HdlUnitKind:ident]
#[unit_kind = $UnitKind:ident]
#[hdl]
#[hdl(custom_debug(sim))]
$(#[$enum_meta:meta])*
$vis:vis enum $UnitMOpEnum:ident<$DestReg:ident: Type, $SrcRegWidth:ident: Size, #[MOp(get_ty = $transformed_move_op_get_ty:expr)] $TransformedMoveOp:ident: Type> {
$(
@ -82,9 +82,8 @@ macro_rules! all_units {
}
mop_enum! {
#[debug(where $TransformedMoveOp: crate::instruction::MOpDebug)]
#[impl_mop_into = false]
#[hdl]
#[hdl(custom_debug(sim))]
$(#[$enum_meta])*
$vis enum $UnitMOpEnum<
$DestReg: Type,
@ -322,7 +321,7 @@ macro_rules! all_units {
all_units! {
#[hdl_unit_kind = HdlUnitKind]
#[unit_kind = UnitKind]
#[hdl]
#[hdl(custom_debug(sim))]
pub enum UnitMOp<
DestReg: Type,
SrcRegWidth: Size,

8
crates/cpu/tests/next_pc.rs
View file

@ -1163,13 +1163,7 @@ impl MockExecuteState {
id: &insn.id,
next_pc,
call_stack_op: mock_insn.call_stack_op(pc),
cond_br_taken: if let Some(cond_br_taken) = cond_br_taken {
#[hdl(sim)]
HdlSome(cond_br_taken)
} else {
#[hdl(sim)]
HdlNone()
},
cond_br_taken,
config: self.config,
},
)

58
crates/cpu/tests/rename_execute_retire.rs
View file

@ -9,8 +9,8 @@ use cpu::{
instruction::{
AddSubMOp, AluBranchMOp, AluCommonMOp, BranchMOp, COMMON_MOP_SRC_LEN, CommonMOp,
CompareMOp, CompareMode, ConditionMode, L2RegisterFileMOp, LoadMOp, LoadStoreCommonMOp,
LoadStoreConversion, LoadStoreMOp, LoadStoreWidth, MOp, MOpDebug, MOpDestReg, MOpRegNum,
MOpTrait, MoveRegMOp, OutputIntegerMode, PRegNum, StoreMOp, UnitNum,
LoadStoreConversion, LoadStoreMOp, LoadStoreWidth, MOp, MOpDestReg, MOpRegNum, MOpTrait,
MoveRegMOp, OutputIntegerMode, PRegNum, StoreMOp, UnitNum,
},
next_pc::CallStackOp,
register::{PRegFlags, PRegFlagsPowerISA, PRegValue},
@ -1817,20 +1817,8 @@ impl<C: PhantomConstCpuConfig> MockUnitOp<C> {
mop,
src_values,
sent_cant_cause_cancel,
output_ready: if let Some(output_ready) = output_ready {
#[hdl(sim)]
output_ready_ty.HdlSome(output_ready)
} else {
#[hdl(sim)]
output_ready_ty.HdlNone()
},
caused_cancel: if let Some(caused_cancel) = caused_cancel {
#[hdl(sim)]
caused_cancel_ty.HdlSome(caused_cancel)
} else {
#[hdl(sim)]
caused_cancel_ty.HdlNone()
},
output_ready: output_ready.into_sim_value_with_type(output_ready_ty),
caused_cancel: caused_cancel.into_sim_value_with_type(caused_cancel_ty),
config,
}
}
@ -1842,11 +1830,7 @@ impl<C: PhantomConstCpuConfig> MockUnitOp<C> {
let (output, caused_cancel) =
execution_state.run_mop(&self.mop, &self.src_values, self.config);
assert!(output.is_some() || caused_cancel.is_some());
println!(
"try_run: {:#x}: {}",
self.mop.pc.as_int(),
fmt::from_fn(|f| MOpDebug::mop_debug(&self.mop.mop, f)),
);
println!("try_run: {:#x}: {:?}", self.mop.pc.as_int(), self.mop.mop);
println!(
"<- {:?}",
self.src_values
@ -1985,20 +1969,8 @@ impl<C: PhantomConstCpuConfig, E: MockExecutionStateTrait> MockUnitState<C, E> {
if op.output_ready.is_none() && op.caused_cancel.is_none() {
continue;
}
let output_ready = if let Some(output_ready) = &op.output_ready {
#[hdl(sim)]
output_ready_ty.HdlSome(output_ready)
} else {
#[hdl(sim)]
output_ready_ty.HdlNone()
};
let caused_cancel = if let Some(caused_cancel) = &op.caused_cancel {
#[hdl(sim)]
caused_cancel_ty.HdlSome(caused_cancel)
} else {
#[hdl(sim)]
caused_cancel_ty.HdlNone()
};
let output_ready = op.output_ready.to_sim_value_with_type(output_ready_ty);
let caused_cancel = op.caused_cancel.to_sim_value_with_type(caused_cancel_ty);
// TODO: add delay
return (
output_ready,
@ -2301,20 +2273,8 @@ impl<C: PhantomConstCpuConfig> MockLoadStoreOp<C> {
MockLoadStoreOpDebugState::<_> {
mop,
is_speculative,
src_values: if let Some(v) = src_values {
#[hdl(sim)]
HdlSome(v)
} else {
#[hdl(sim)]
HdlNone()
},
dest_value: if let Some(v) = dest_value {
#[hdl(sim)]
HdlSome(v)
} else {
#[hdl(sim)]
HdlNone()
},
src_values,
dest_value,
ran_nonspeculatively,
sent_cant_cause_cancel,
sent_output_ready,

11
crates/cpu/tests/simple_power_isa_decoder/main.rs
View file

@ -152,16 +152,7 @@ fn test_decode_insn() {
} in test_cases::test_cases()
{
sim.write(sim.io().first_input, first_input);
sim.write(
sim.io().second_input,
if let Some(v) = second_input {
#[hdl(sim)]
HdlSome(v)
} else {
#[hdl(sim)]
HdlNone()
},
);
sim.write(sim.io().second_input, second_input);
sim.advance_time(SimDuration::from_micros(1));
let second_input_used = sim.read_bool(sim.io().second_input_used);
let is_illegal = sim.read_bool(sim.io().is_illegal);

8
crates/cpu/tests/simple_power_isa_decoder/test_cases/fixed_point_rotate_and_shift.rs
View file

@ -30,13 +30,7 @@ fn rotate_imm(
) -> SimValue<ShiftRotateMOpImm> {
#[hdl(sim)]
ShiftRotateMOpImm {
shift_rotate_amount: if let Some(amount) = amount {
#[hdl(sim)]
HdlSome(amount.cast_to_static::<UInt<_>>())
} else {
#[hdl(sim)]
HdlNone()
},
shift_rotate_amount: amount.map(|amount| amount.cast_to_static::<UInt<_>>()),
shift_rotate_right: false,
dest_logic_op: if let Some((rotated_output_start, rotated_output_len)) =
rotated_output_start_and_len